JP2000016769A - Lever type hoist - Google Patents

Abstract

PROBLEM TO BE SOLVED: To surely lock both the end parts of a conterclockwise coil spring arranged between a pressure receiving member and a press driving member, in a lever type hoist for eliminating the operation of an operating wheel at the start of idling, and performing idling action in a moment. SOLUTION: In a hoist for turning a pressure receiving member 6 fixed to a driving shaft 5 by a press driving member 7, via a reversal preventing wheel 10 and a pair of friction members 8 and 9 arranged in both the surfaces of the wheel 10; the driving member 7 is formed so as to open a spring arranging hole 71, arranged with the tip part 13d of a counterclockwise coil spring 13 in an axial direction base end side, and also so as to open a second locking groove 7e, extending outward in the radial direction, in the axial direction base end side in the periphery of the hole 71. The groove 7e is tiltedly formed in a lowering direction with near to an axial direction tip side, and the crossing angle α between the tilt surface 7k on the lowering side of the groove 7e and the axial direction base end surface 7e of the driving member 7j, is formed an acute angle.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lever-type hoisting machine, and in particular, does not require the operation of operating wheels at the start of idle rotation.
The present invention relates to a lever type hoisting machine capable of performing an idle operation instantly.

[0002]

2. Description of the Related Art As a lever type hoisting machine which does not require the operation of operating wheels at the start of idle rotation, the applicant has previously disclosed in Japanese Patent Laid-Open No.
No. 59689 has been proposed. This lever type hoisting machine is a hoisting machine having a configuration in which a pressure receiving member fixed to a drive shaft is rotated by a pressing drive member via a reverse rotation preventing wheel and a pair of friction members disposed on both surfaces thereof. A coil spring is interposed between the pressure receiving member and the pressing drive member so as to apply a rotational force in a direction to release the pressing of the pressing drive member against the pressure receiving member. Incidentally, the pressure receiving member is formed with a boss hole which is opened at the front end side in the axial direction, and is formed with a rectangular first locking groove extending radially outward around the boss hole. Was.
As shown in FIG. 6, a spring arrangement hole B is formed in the pressing drive member A so as to open to the base end side in the axial direction, and extends radially outward around the spring arrangement hole. Thus, the second locking groove C was formed. And the first of the pressure receiving members
The proximal locking portion of the coil spring is locked in the locking groove, and the proximal portion of the coil spring is arranged in the boss hole, while the distal locking portion E of the coil spring D is engaged in the second locking groove of the pressing drive member. The configuration is such that the end of the coil spring is arranged in the spring arrangement hole.

[0003]

However, in the lever type hoist of the above construction, the angle of intersection between the end face on the upper side of the first locking groove and the axial end face of the pressure receiving member, and the second locking groove. And the intersection angle between the end face on the unwinding side and the base end face in the axial direction of the pressing drive member is formed at right angles. For example, FIG.
Is a cross-sectional view showing a second locking groove C of the pressing drive member A. As shown in FIG.
And the intersection angle between the pressing drive member and the axial base end face F is 90.
° had been. That is, the angle of the locking surface is 90 ° conventionally.
Or more than that, so
In some cases, a proximal locking portion and a distal locking portion bent at both ends of the coil spring are arranged at the top of the locking surface. Therefore, when an external impact or the like is applied to the lever handle or the like, each of the locking portions of the coil spring comes off from the apex portion, and the spring force for rotating the pressing drive member in the counterclockwise direction does not work. There was a possibility that the state could not be performed. The present invention has been made to solve the above problems.

[0004]

SUMMARY OF THE INVENTION The present invention provides a driving shaft having a base end connected to a load sheave via a gear transmission system, a pressure receiving member fixed to the driving shaft, and an axial direction of the pressure receiving member. On the distal end side, the pressing drive member is provided to be screwed forward and backward on the drive shaft, and is rotated by an operation handle as necessary, and is interposed between the pressure receiving member and the pressing drive member, A reverse rotation prevention wheel provided so as to be rotatable only in the hoisting direction, and a pair of friction members disposed on both surfaces of the reverse rotation prevention wheel and provided so as to be able to be pressed by the pressing drive member, and a base end and a front end, respectively. The present invention is applied to a lever-type hoisting machine having a proximal locking portion and a distal locking portion extending radially outward and having a left-handed coil spring interposed between the pressure receiving member and the pressing drive member. Things.
And in order to solve the said subject, in this invention, in the said lever-type hoisting machine, the boss hole in which the base end part of the said left-handed coil spring is arrange | positioned to the axial direction front-end side is provided in the said pressure-receiving member. In addition, a first locking groove extending radially outward is formed around the boss hole so as to open toward the distal end in the axial direction, and the distal end of the left-handed coil spring is disposed on the pressing drive member. A spring arrangement hole is formed so as to open to the base end side in the axial direction, and around the spring arrangement hole,
A second locking groove extending outward in the radial direction is formed so as to open toward the base end in the axial direction, and the second locking groove is formed so as to be inclined in the lowering direction toward the distal end in the axial direction. , The second
The crossing angle between the inclined surface on the lower side of the locking groove and the axial base end surface of the pressing drive member is formed at an acute angle, and the base engagement of the left-handed coil spring is formed in the first locking groove of the pressure receiving member. The stop portion is locked to prevent rotation of the left-handed coil spring in the hoisting direction with respect to the pressure receiving member, while the distal end locking portion of the left-handed coil spring is locked in the second locking groove of the pressing drive member. Thus, the rotation of the pressing drive member in the hoisting direction with respect to the left-handed coil spring is prevented. Preferably, in addition to the above configuration, the first
The locking groove is formed so as to be inclined in the hoisting direction toward the base end side in the axial direction, and the intersection between the inclined surface on the winding upper side of the first locking groove and the axial end surface of the pressure receiving member. The lever-type hoist according to claim 1, wherein the angle is formed to be an acute angle.

[0005]

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the lever type hoist of the present invention will be described in more detail. FIG. 1 is a longitudinal sectional view showing an embodiment of a lever type hoist according to the present invention.
FIG. 2 is an exploded perspective view showing a main part of the lever type hoisting machine. In FIG. 1, a load sheave 3 is provided between a pair of side plates 1 and 2 held in parallel at a predetermined interval, and the load sheave 3 is rotatably held by bearings 4 and 4. I have. Shaft hole 3 in the center of load sheave 3
The drive shaft 5 is rotatably inserted into the shaft hole 3a. Both ends of the drive shaft 5 protrude from the left and right ends of the load sheave 3. A means for driving the load sheave 3 is provided on the right protrusion of the drive shaft 5. The first screw portion 5a, the shaft portion 5b, the spline portion 5c, and the protruding portion are arranged in this order from the base end side, with the side closer to the side plate 2 as the base end, and the right side apart from the side plate 2 as the tip end direction. A second screw portion 5d is formed. Each of the screw portions 5a and 5d is a right-hand thread. On the other hand, a pinion gear G ₁
Is fixed, and this is a reduction gear transmission system G ₂ , G ₃ ,
It is connected to the load sheave 3 through G _4. In addition,
Each of the gears G _{1 to} G ₄ has a cover 3 attached to the side plate 1.
2 is covered.

[0006] A pressure receiving member 6 and a pressing drive member 7 are screwed into the first screw portion 5a of the drive shaft 5 from the side closer to the side plate 2, and the pressure receiving member 6 is connected to the first screw portion 5a. It is screwed down to the inside and fixed. The pressure receiving member 6 has a disk portion 6a and a boss portion 6b.
Is close to the side plate 2, and the boss portion 6b is formed so as to protrude from the center of the disk portion 6a toward the front end in the axial direction. Pressure receiving member 6
A boss hole 6c slightly larger in diameter than the outer diameter of the left-handed coil spring 13 is formed in the boss portion 6b. Further, a part of the peripheral wall of the boss hole 6c is formed with a first locking groove 6d reaching the bottom surface of the boss hole 6c from the axial end surface 6e toward the axial base end.
The boss 6b is fitted with a pair of friction members 8, 9 and an anti-reverse wheel 10 sandwiched therebetween.

FIG. 3 is a plan view of the pressure receiving member 6, and FIG.
FIG. 6 is a sectional view of a first locking groove 6 d formed in the pressure receiving member 6. As shown in FIG. 3, the first locking groove 6d is formed in a substantially V-shape so as to be inclined in the hoisting direction toward the base end side in the axial direction. Slope 6
and the intersection angle α between the pressure receiving member 6 and the axial end surface 6e of the pressure receiving member 6.
Have an acute angle as shown in FIG. In the illustrated example, an example is shown in which the cross angle α is set to, for example, about 60 °, but this angle α can be changed as appropriate within a range of less than 90 °.

The anti-reverse wheel 10 has, on its outer periphery, locking teeth which are inclined in one direction in the circumferential direction. The reverse rotation preventing wheel 10 and the friction members 8 and 9 disposed on both sides thereof are pressed by a pressing drive member 7, and the disc portion 6 a of the pressure receiving member 6 and the pressing drive member 7 It is configured to be sandwiched between. The ratchet pawl 11 is pivotally supported by the side plate 2, and a spring 12 prevents the reverse rotation preventing wheel 10.
Is pressed against the outer peripheral portion of. This ratchet claw 11
Are engaged with the locking teeth of the anti-reverse wheel 10 to lock the anti-reverse wheel 10 so that it can rotate only in the hoisting direction of the load sheave 3.

The pressing and driving member 7 screwed to the first screw portion 5a so as to be able to advance and retreat in the axial direction may be formed integrally as shown in FIG. 1, but as shown in FIG. -1 and the pressing plate 7-2. FIG. 5 is a perspective view of the main body portion 7-1 of the pressing drive member 7 as viewed from the base end side in the axial direction. When the main body 7-1 and the pressing plate 7-2 are formed separately, the enlarged-diameter protrusion 7g formed on the annular protruding portion 7f of the main body 7-1 is formed on the pressing plate 7-2. The main body portion 7-1 and the pressing plate 7-2 operate integrally by being provided between the reduced diameter projecting portions 7x and the enlarged diameter projecting portion 7g abutting against the reduced diameter projecting portion 7x. It is configured to be. In addition, even when the pressing plate 7-2 bites into the friction member 9 due to the load, the main body 7
Since the large-diameter projection 7g of -1 is disposed between the reduced-diameter projections 7x of the pressing plate 7-2, the main body 7-1 and the pressing plate 7-2 can be slightly rotated relative to each other. The urging (biting) of the pressing plate 7-2 against the friction member 9 or the like is released by rotating the main body 7-1 by operating the operation handle 18 and applying an impact rotational force to the pressing plate 7-2. Can be. Press drive member 7
Has an annular concave hole 7a (7a-
1, 7a-2) are formed, and a first ridge 7b and a second ridge 7c extending in the radial direction are provided in the annular concave hole 7a. Thereby, as shown in FIG. 2, the annular concave hole 7a has two portions 7a- having greatly different center angles.
1, 7a-2.

An annular projecting portion 7f is formed on the axially proximal end face of the main body 7-1 of the pressing drive member 7 so as to project toward the axially proximal end. This annular projecting portion 7f is
-1 is formed concentrically with a screw hole formed at the radial center portion, and is formed in an annular shape so as to protrude therefrom. On the peripheral wall, a leading end locking portion 13a of the left-handed coil spring 13 is guided and locked. The second locking groove 7e is formed in at least one place.
In the illustrated example, three second locking grooves 7e are formed at regular intervals of 120 degrees. Note that the inner diameter of the annular projecting portion 7f is a spring arrangement hole 71 having a size substantially compatible with the outer diameter of the left-handed coil spring 13. Each second locking groove 7e is
The annular protruding portion 7f is cut out in a substantially V-shape from the axial base end surface 7j toward the axial distal end, and the distal end is lowered in the axial direction as it goes toward the axial distal end. It is formed so as to be inclined. The cross-sectional shape of the second locking groove 7e is substantially the same as the cross-sectional shape of the first locking groove 6d formed in the pressure receiving member 6, and as shown in FIG. It is formed so as to extend slightly more gradually than the inclined surface 7k on the unwinding side to the base end surface 7j toward the distal end in the axial direction, and the second inclined surface 7h, 7k on the unwinding side intersects with the inclined surface 7h, 7k on the unwinding side. A left-handed coil spring 1 near the bottom of the locking groove 7e
3 is locked. In addition,
The axial depth of the second locking groove 7e is formed to be the same as the bottom surface of the spring arrangement hole 7l. The peripheral side wall of the portion where the second locking groove 7e is formed protrudes radially outward to form an enlarged projection 7g. The pressing plate 7-2 of the pressing drive member 7
It has a short cylindrical shape and an inner diameter slightly larger than the diameter of the enlarged projection 7g of the main body 7-1. On the inner diameter portion of the pressing plate 7-2, a reduced diameter projection 7x having a diameter larger than the diameter of the annular projection 7f of the main body 7-1 and smaller than the diameter expansion projection 7g is provided.
It is formed to protrude radially inward.

A rotation limiting member 14 is provided on the spline portion 5c of the drive shaft 5 adjacent to the pressing drive member 7 by spline connection. The rotation restricting member 14 has a rotation restricting projection 14a formed on an end surface facing the pressing drive member 7, and a boss 14b formed on an end surface on the opposite side to the axial front end side. The positioning of the rotation restricting member 14 with respect to the pressing drive member 7 may be performed, for example, by rotating the pressing restricting member 14 sufficiently in the hoisting direction and pressing the friction member 9 so that the rotation restricting projection 14 a
This is performed by fitting to the spline portion 5c of the drive shaft 5 so as to form an angle of about 30 degrees in the unwinding direction with respect to the ridge 7b.
As described above, the rotation restricting projection 14a protrudes from the larger annular concave hole 7a-1, and the first driving ridge 7b hits the rotation restricting projection 14a. Since it does not rotate as described above, the pressing drive member 7
Is prevented from moving unnecessarily to the distal end in the axial direction.

The left-handed coil spring 13 is literally a left-handed coil spring, and both ends are bent outward in the radial direction to form a distal locking portion 13a and a proximal locking portion 13b. The opening angle between the distal locking portion 13a and the proximal locking portion 13b of the left-handed coil spring 13 is appropriately set, and is, for example, about 60 to 90 °. The left-handed coil spring 13 has a spring force that can be sufficiently lightly lifted when the pressing drive member 7 is wound up with a load applied to the load sheave 3. The left-handed coil spring 13 is loosely fitted to the drive shaft 5, and has a base end 13 c formed in the boss hole 6 of the pressure receiving member 6.
c, and the distal end portion 13d is inserted and arranged in the spring arrangement hole 71 of the pressing drive member 7. In addition,
The left-handed coil spring 13 is configured such that the proximal locking portion 13b is engaged with the first locking groove 6d of the pressure receiving member 6, while the distal locking portion 13b is engaged.
a is engaged with the second locking groove of the pressing drive member 7 and disposed.

In assembling, the left-handed coil spring 13
Of the left-handed coil spring 13 in the boss hole 6c.
When the pressing driving member 7 is screwed along the first screw portion 5a of the driving shaft 5 in a state where the pressing driving member 7 is inserted into the The second locking groove 7e is inserted and engaged. In other words, the distal end locking portion 13a of the left-handed coil spring 13 is formed by being formed so as to be deeper as it moves in the lowering direction along the inclined surface 7h on the upper side of the winding, by screwing the pressing drive member 7 in the raising direction. It is automatically guided to the back of the second locking groove 7e. Further, if a plurality of second locking grooves 7e are formed in the pressing drive member 7, the pressing drive member 7 is locked every one-hundredth rotation in the hoisting direction, and the locking with the left-handed coil spring 13 is further improved. This is preferable because it is easy and the left-handed coil spring 13 can be set to an optimum strength. By such an operation, the proximal locking portion 13b of the left-handed coil spring 13 is also guided to the depth of the first locking groove 6d, and is reliably engaged with the pressure receiving member 6. In addition,
The locking portions 13a, 13b of the left-handed coil spring 13 are guided to the depths of the respective locking grooves 7e, 6d also by the axial spring force of the left-handed coil spring 13.

As a result, the proximal locking portion 13b of the left-handed coil spring 13 is locked in the first locking groove 6d, and the distal locking portion 13a is locked in the second locking groove 7e. When rotated in the hoisting direction, the left-handed coil spring 13 is deformed, and a circumferential urging force acts on the pressing drive member 7 in a direction of retreating from the pressure receiving member 6 to the tip end in the axial direction. The pressing drive member 7 has a rotational force for rotating the pressing drive member 7 in a counterclockwise direction to retreat the pressing drive member 7 along the drive shaft 5. Is also exerted in the axial direction to urge. Conversely, when replacing worn parts such as the friction members 8 and 9, it is necessary to disassemble them. When disassembling, when the pressing drive member 7 is rotated in the unwinding direction, the leading end of the left-handed coil spring 13 is disengaged. The stopper 13a slides on the inclined surface 7h on the upper side of the winding up of the second locking groove 7e and separates from the second locking groove 7e, so that the pressing drive member 7 can be continuously rotated in the lowering direction without any trouble. And can be decomposed in a short time.

An operating wheel 16 is rotatably fitted to the rotation restricting member 14 on the outer periphery of the boss 14b of the rotation restricting member 14. The operation wheel 16 is provided with the rotation restricting member 14.
Are formed so as to be in surface contact with each other at an outer peripheral portion thereof, and a concave portion 16c is formed at a tip end side in the axial direction. Further, an uneven portion is formed on the outer periphery of the operation wheel 16,
The operation wheel 16 is easy to hold and turn. On the bottom wall of the operation wheel 16 facing the pressing drive member 7,
Press release projection 1 that projects into the smaller annular concave hole 7a-2
6a is provided. The pressing release projection 16a collides with the second ridge 7c of the pressing driving member 7, and the pressing driving member 7
Then, the pressing drive member 7 is moved to the tip end in the axial direction by the rotation due to the inertia or forced rotation in the unwinding direction.

In the recess 16c of the operating wheel 16, a washer 1 is provided.
A nut 7 is inserted into the shaft hole 17a of the drive shaft 5 and accommodated therein.
5, the operation wheel 16 is fixed to the inner surface of the bottom wall. Washer 17
Is formed somewhat larger than the diameter of the shaft hole 16d formed in the bottom wall of the operation wheel 16. Therefore, the operation wheel 16
The operation wheel 16 does not come off from the rotation restricting member 14 even when is pulled outward, and there is no possibility that the engagement between the pressing release projection 16a and the two ridges 7b and 7c may come off. In addition,
The rotation limiting member 14 has an end surface of the boss 14 b
Is formed to be slightly lower than the inner surface of the bottom wall.

The gear 7d of the pressing drive member 7 is housed in the operation handle 18. Operation handle 18
Is composed of an inner case 18a and an outer case 18b. The inner case 18a has an opening surrounding the friction member 9 side of the pressing drive member 7, and the outer case 1
8b is provided with an opening surrounding the outer periphery of the bottom wall portion 16b of the operation wheel 16. These inner case 18a and outer case 18b are provided with a plurality of screws 19, 19,.
, 0, 20,...

The operation handle 18 extends below the pressing drive member 7 and has a rotation direction switching claw 22 provided inside thereof. The rotation direction switching claw 22
The handle 21 is rotatably held by the handle 21 with respect to the handle cases 18a and 18b. The shaft 21 is the operation handle 1
8, and a switching lever 23 for switching is attached to the protruding portion. By switching the switching lever 23, the rotation direction switching claw 22 is engaged so that the pressing drive member 7 is rotated in the hoisting direction (UP) or the hoisting direction (DOWN).
It is held in a neutral position that does not rotate in either direction.
A pressing member 24 urged upward by a spring 25 is in contact with the lower end of the rotation direction switching claw 22, whereby the rotation direction switching claw 22 is elastically held at a predetermined switching position.

An upper hook 2 is provided on the upper portion between the side plates 1 and 2.
7 is provided via a connection fitting 26. At the lower end of the load chain 28 wound around the load sheave 3,
A lower hook 30 for hanging a load is connected via a connection fitting 29. Numeral 31 denotes a stopper for removing the luggage, which is pivotally mounted on the upper portion of the lower hook 30 so as to be rotatable only inward. Reference numeral 33 denotes a cover attached to the side plate 2 by a plurality of screws 35 and nuts 36. The cylindrical opening at the center of the cover 33 is superimposed on the outer periphery of the cylindrical opening of the inner case 18a so that the operation handle 18 can reciprocate. A stopper tubular member 34 having a U-shaped cross section that restricts the axial movement of the operation handle 18 is fitted into the inner surface of the tubular opening of the inner case 18a. The stopper tube member 34 is made of, for example, a steel plate.

Next, the operation of the lever type hoist of this embodiment will be described. When the idle operation is performed, the switching lever 23 is set to the neutral position. When the switching lever 23 is set to the neutral position, in a no-load state, the urging force of the left-handed coil spring 13 causes the pressing drive member 7 to rotate instantaneously in the lowering direction, and the shaft is moved along the first screw portion 5 a of the drive shaft 5. In the direction of the direction, and releases the pressing with the friction member 9. Therefore, without operating and rotating the operation wheel 16,
By pulling the chain 28, the idle operation can be performed immediately. The pressing drive member 7 is prevented from further retreating toward the axial front end by the first protrusion 7b abutting on the rotation restricting projection 14a of the rotation restricting member 14. On the other hand, since the spring force of the left-handed coil spring 13 is for idling operation and is weak, in a loaded state where the load is applied, the drive shaft 5 is moved counterclockwise by the weight of the load in the direction in which the load is unwound. , And the locking teeth of the anti-reverse wheel 10 are engaged with the ratchet pawl 11 of the ratchet gear, so that the pressing drive member 7 rotates in the hoisting direction, and the friction members 8, 9 And the reverse rotation preventing wheel 10 is pressed against the pressure receiving member 6 to maintain the brake state, which is safe.

When the load is to be hoisted, the switching lever 23 is switched to the hoisting direction (UP), and then the operating handle 18 is rotated back and forth about the drive shaft 5 to reciprocate. . In addition, when unloading and unloading the luggage, the switching lever 23 is switched in the unwinding direction (DOWN), and then the operation handle 18 is rotated back and forth about the drive shaft to reciprocate.

According to the lever type hoist of the above-described embodiment, the left-handed coil spring 13 disposed between the pressure receiving member 6 and the pressing and driving member 7 presses the pressing and driving member 7 away from the pressure receiving member 6. A circumferential urging force is applied to the driving member 7. Therefore, only by setting the switching lever 23 to the neutral state,
The pressing drive member 7 automatically and continuously separates from the pressure receiving member 6. For this reason, the idle operation can be performed without requiring the operation of the operation wheel 16. In addition, since the second locking groove 7e is formed in the pressing drive member 7, the left-handed coil spring 13 can be arranged at an appropriate position only by screwing the pressing drive member 7 along the drive shaft 5, so that assembly is possible. And productivity is improved. Furthermore, since the left-handed coil spring 13 disposed between the pressure receiving member 6 and the pressing drive member 7 can be disposed without requiring a gap between the two members, the first of the pressure receiving member 6
Since the locking groove 6d and the second locking groove 7e of the pressing drive member 7 are securely locked, there is no possibility that the locking between the pressure receiving member 6 or the pressing drive member 7 and the left-handed coil spring 13 is released,
It is safe.

[0023]

As described above in detail, according to the lever type hoist of the present invention, at least the lower side surface of the second locking groove of the pressing drive member for locking the distal end locking portion of the left-handed coil spring is formed. The first locking groove of the pressure-receiving member, which is formed on the inclined surface and preferably locks the base locking portion of the left-handed coil spring, is also formed on the inclined surface. Then, the angle of intersection between the lower inclined surface of the second locking groove and the axial base end surface of the pressing drive member, and preferably, in addition thereto, the upper inclined surface of the first locking groove, The angle of intersection of the member with the axial end surface is set to an acute angle, that is, less than 90 °. Therefore, the proximal locking portion and the distal locking portion, which are bent at both ends of the left-handed coil spring, respectively,
As it enters into the locking groove or the second locking groove and does not come off once it enters, it can be used continuously and stably.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing one embodiment of a lever type hoist of the present invention.

FIG. 2 is an exploded perspective view showing a main part of the lever-type hoist shown in FIG.

FIG. 3 is a plan view of a pressure receiving member of the lever type hoist shown in FIG. 1;

FIG. 4 is a sectional view of a first locking groove or a second locking groove of the lever type hoist shown in FIG. 1;

FIG. 5 is a perspective view of a pressing drive member and a left-handed coil spring of the lever-type hoisting machine of FIG. 1 as viewed from a base end side in the axial direction.

FIG. 6 is a perspective view of a pressing drive member and a coil spring of a conventional lever-type hoisting machine as viewed from an axial base end side.

FIG. 7 is a sectional view of a second locking groove of a conventional lever type hoisting machine.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 3 Load sheave 5 Drive shaft 5a, 5d Screw part 5c Spline part 6 Pressure receiving member 6a Disk part 6b Boss part 6c Boss hole 6d First locking groove 6e Axial front end face 6f Inclined surface on top of winding 7 Press drive member 7a Annular concave part Hole 7b First ridge 7c Second ridge 7e Second locking groove 7f Annular projection 7g Larger diameter projection 7h Raised surface 7j Axial base end surface 7k Lower inclined surface 7l Spring arrangement hole 7x Reduced-diameter protrusion 8, 9 Friction member 10 Reverse rotation prevention ring 13 Left-handed coil spring 13a Tip locking portion 13b Base locking portion 13c Base portion 13d Tip portion 14 Rotation restricting member 14a Rotation restricting protrusion 15 Nut 16 Operating wheel 18 Operating handle 22 rotation direction switching pawl 23 rocking bar G ₁ pinion gear G ₂ ~G ₄ reduction gear transmission sequence

Claims (2)

[Claims] 1. A drive shaft having a base end connected to a load sheave via a gear transmission system, a pressure receiving member fixed to the drive shaft, and an axial front end side of the pressure reception member on the drive shaft. A pressing drive member that is provided so as to be able to advance and retreat, and is rotated by an operation handle as necessary, and is interposed between the pressure receiving member and the pressing drive member, and is rotatable only in the hoisting direction. A provided anti-reverse wheel, a pair of friction members disposed on both surfaces of the anti-reverse wheel, and provided so as to be capable of being pressed by the pressing drive member, and having a base end and a distal end extending radially outward, respectively. In a lever-type hoisting machine having an end locking portion and a tip locking portion, and a left-handed coil spring interposed between the pressure receiving member and the pressing drive member, the pressure receiving member includes a left-handed coil spring, Base end is placed A boss hole is formed so as to open toward the tip end in the axial direction, and a first boss hole extending radially outward is formed around the boss hole.
A locking groove is formed by opening to the axial distal end side, and a spring arrangement hole in which the distal end portion of the left-handed coil spring is disposed is formed by opening in the axial base end side in the pressing drive member. Around the spring arrangement hole, a second locking groove extending radially outward is formed by opening toward the base end in the axial direction. A crossing angle between an inclined surface on the lower side of the second locking groove and an axial base end surface of the pressing drive member is formed at an acute angle; The base locking portion of the left-handed coil spring is locked in the one locking groove to prevent the left-handed coil spring from rotating in the hoisting direction with respect to the pressure receiving member, while the second locking groove of the pressing drive member is provided. The leading end locking portion of the left-handed coil spring is locked to the left-handed coil spring. A lever type hoisting machine wherein rotation of the pressing drive member in the hoisting direction is prevented. 2. The first locking groove is formed so as to be inclined in a hoisting direction toward the base end side in the axial direction, and an inclined surface on an upper side of the first locking groove and the pressure receiving member. The lever-type hoisting machine according to claim 1, wherein an intersection angle between the first and second axial ends is formed at an acute angle.